Special features: • Provides more than 1500 outstanding color photographs that show the sequence of steps for all procedures involving self-ligating brackets from start to finish • Objectively evaluates the advantages and disadvantages of commercially available self-ligating bracket systems to help you make the best choices for your patients • Covers the full scope of treatment, including oral hygiene, adhesive techniques, biomechanics, esthetic choices, retention and stability, and more • Includes multiple case studies as well as information on risks, pitfalls, practical tips, and clinical pearls that aid in decision-making and reinforce the treatment concepts Written by a team of international specialists, this book is a quintessential guide for all practitioners who want to keep up to date with the latest developments in self-ligating brackets and offer state-of-the-art treatment techniques for their patients. This book is designed to be a useful introduction to newcomers to self-ligation as well as a guide for experienced orthodontists on how to successfully incorporate this highly popular technique into their practices. Bjoern Ludwig, MD, is Associate Professor at the University Clinic Homburg/Saar and in Private Practice in Traben-Trarbach, Germany. Dirk Bister, MD, DD, MOrth RCS Edinburgh, is Consultant Orthodontist, Guy’s and St. Thomas’ Dental Hospital, London, and Addenbrooke’s Hospital, Cambridge, UK. Sebastian Baumgaertel, DMD, MSD, FRCD(C), is Clinical Associate Professor, Department of Orthodontics, School of Dental Medicine, Case Western Reserve University, Cleveland, Ohio, USA. An award-winning international medical and scientific publisher, Thieme has demonstrated its commitment to the highest standard of quality in the state-of-the-art content and presentation of all of its products. Thieme’s trademark blue and silver covers have become synonymous with excellence in publishing.
ISBN 978-3-13-154701-9
www.thieme.com
Self-Ligating Brackets
Promising numerous advantages in design, treatment efficacy, and reduced treatment time, self-ligating brackets have become a major part of modern orthodontic practice. Self-Ligating Brackets in Orthodontics: Current Concepts and Techniques summarizes contemporary information and clinical studies on these popular systems, integrating them with the authors’ practical and hands-on experience. Encompassing all aspects of treatment with self-ligating fixed appliances from biomechanics to material properties and also including diagnostic and therapeutic principles, this book provides a step-by-step visual guide to this groundbreaking field.
Ludwig / Bister Baumgaertel
A comprehensive overview of modern orthodontic treatment using self-ligating bracket systems—with evaluations of systems currently available
Self-Ligating Brackets in Orthodontics Current Concepts and Techniques
Bjoern Ludwig Dirk Bister Sebastian Baumgaertel
Treatment Bjoern Ludwig and Bettina Glasl
7 Space Creation Alignment
Correction of Skeletal Discrepancies
98
98
Space Creation through Distalization 124 Space Creation by Expansion of Arches 135
Correction of Class III Malocclusions 155
Space Creation by Extracting Teeth 142
Esthetic Treatment
Space Creation by Interproximal Reduction (IPR)
148
Correction of a Class II Buccal Segment Relationship
159
Self-Ligating Ceramic Brackets 148
148
Lingual Self-Ligating Brackets
159 163
98
7
Treatment 1. Alignment Enamel reduction
Protrusion
Extraction
Expansion
Distalization
Fig. 7.1 Options for creating space in a dental arch.
Space Creation The possibilities for creating space are the same whether self-ligating techniques are employed or conventional ligation is used (Fig. 7.1). Space can be created by protrusion of the front teeth, expansion of the posterior dentition, distalization of the posterior dentition, reducing the number of teeth by extraction or by interproximal enamel reduction (stripping)—or a combination of some or all of the above.
Alignment The first phase of orthodontic treatment immediately after placement of brackets consists of leveling and alignment of the dental arches. This stage of the treatment is usually concerned with derotation and alignment of misplaced teeth into the arch. In a large number of patients, this is the only treatment aim. In others, however, additional treatment aims need to be pursued such as coordination of the dental arches, closure or opening of spaces, correction of the occlusion, or even decompensation of the dental arches before orthognathic surgery (Fig. 7.2). One of the major advantages of self-ligation is reduced friction between the archwire and the brackets, which should lead to more rapid alignment during the first phase of orthodontic treatment. It is very useful if this phase of the orthodontic treatment can be shortened to allow the other aims of treatment to be pursued in a more timely fashion.
Biomechanics In 1932, Schwarz postulated that orthodontic forces applied to a tooth should not be greater than the capillary pressure of its periodontal ligament, which is in the range of 0.22–0.26 N/cm2 of root surface, to avoid hyalinization
– Alignment of displaced teeth – Derotation – Correction of tooth inclination torque – Arch shape development – Leveling
Treatment goal attained, retention phase
2. Main treatment phase – – – –
Dental arch coordination Space closure/opening Bite correction Presurgical decompensation
Treatment goal attained, retention phase
Fig. 7.2 Phases of treatment and treatment goals. and subsequent root resorption. The following criteria determine the level of orthodontic force applied: • The force required to move a tooth into the desired position (for example, uprighting, physical translation, extrusion, intrusion, or derotation) (Table 7.1). • The effective force that the orthodontic appliances actually exert on the tooth (Table 7.2). • The reactive force, which according to Newton’s third law of motion (that action and reaction are equal and opposite) can lead to a reduction in the force acting on the target tooth.
NOTE Action and reaction are equal and opposite (Newton’s third law of motion).
The initial phase of orthodontic tooth movement involves light and flexible archwires that express relatively low and constant force levels. The archwire sizes are subsequently increased gradually until this phase of the treatment has been completed. The amount of force necessary to achieve any particular tooth movement is expressed by the size of the archwires and the material used, as these directly relate to the clinical force levels exerted on the target teeth (Fig. 7.3). The resulting forces observed in a clinical scenario often do not correlate directly with those found in experimental situations (Fig. 7.3 and Table 7.1). It is well known that some orthodontic tooth movements take effect more quickly than others: extrusion and elongation of teeth are some of the quickest movements, followed by tipping, which in turn is followed by translation of teeth. Torque expression and intrusion of teeth are the slowest observed movements (Table 7.3).
Space Creation Table 7.1 Recommended force levels by type of tooth movement. The table gives values from the orthodontic literature. Although some of the quoted data are from very old sources that go back more than 50 years, the values are still taught in orthodontic programs today. Agreement on these values is based on the recommendation of different force levels for different types of tooth movement, which are correlated with the root surface areas of different teeth. See Fig. 7.3
Table 7.2 Force levels for various wires with self-ligating brackets. These values are derived from materials-science experiments that allow comparison. There is a lack of standards for material properties, and this table reflects our own measurements
Archwire dimension and type
Force direction Vertical
Horizontal
Type of tooth movement
Incisors, premolars
Canines, molars
0.010 NiTi
0.1 N
0.2 N
0.012 NiTi
0.2–0.4 N
0.2–0.5 N
Tipping
0.2–0.3 N
0.5–0.75 N
0.014 NiTi
0.2–0.4 N
0.2–0.7 N
Physical translation
0.4–0.5 N
1.5–2.5 N
Extrusion/ intrusion
0.15–0.3 N The values for intrusion and extrusion are clinically, empirically, and physically suspect; the same value is used for intrusion and extrusion
Table 7.3
1. Extrusion/ elongation along the long axis 2. Tipping 3. Physical translation 4. Root torque 5. Intrusion along the long axis
NOTE Orthodontic force levels encountered empirically often do not correlate directly with force levels obtained by experimental studies.
From the biomechanical point of view, self-ligating brackets were developed to reduce the friction of the wire in the bracket slot. Tight ligation of the wires with elastic or wire ligatures actually counteracts the requirements of sliding mechanics. Reports in the literature have shown that frictional resistance reduces the resulting force levels by 50% or more.2,7,26 For self-ligating brackets, friction can be significantly lower in comparison with normal ligation (between 14% and 40%). However, it is a matter of controversy whether these results derived from ex-vivo situations can be applied to the clinical situation, and it is therefore the individual practitioner who needs to interpret the data available and reach appropriate conclusions for treatment planning of each individual case. A classic example is used here to illustrate the potential physiological benefits of self-ligating brackets (Fig. 7.4). This particular patient presented with a maxillary tooth size–arch length discrepancy (TSALD) and labially crowded canines. Extrusion of the canines requires very little force, while intrusion of the neighboring teeth is very slow and requires greater force levels. The initial archwire was a 0.012 superelastic archwire, which typically creates a force of between 0.2 and 0.5 N; this extrudes the canines but the force levels are well below what is needed for effective intrusion of the neighboring teeth. However, the forces exerted by the archwire are sufficiently large to allow proclination of the incisors. Alignment and space creation result from protrusion of the maxillary anterior segment (Fig. 7.4c, d).
The time required for various types of tooth movement
Rapid
Slow
a
b
Slow = difficult
Rapid = easy
Fig. 7.3a, b Finite-element method (FEM) analysis of root surfaces during intrusion and extrusion. Intrusion of teeth can be compared with forcing a wooden peg into the ground; intrusion requires greater force than pulling the peg out. The amount of force necessary to intrude teeth increases proportionately to their root surface area.
99
100
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Treatment 0.15 N 0.30 N
Fig. 7.4a–d Extrusion is possible even with very slight forces of 0.15 N. Reactive intrusion of the surrounding teeth usually starts at force levels of greater than 0.3 N. In order to level teeth by extrusion, only low forces are recommended (0.2 N). See also Chapter 2.
a
b
c
d
a
b
Fig. 7.5a, b An extrusion force of 0.7 N (0.016 superelastic NiTi) can still lead to reciprocal intrusion of the anterior teeth even when a heavy base archwire is used.
This clinical example shows that undesired side effects can largely be avoided by using low force levels in combination with low friction. Using a 0.016 archwire made of the same material would have resulted in force levels of
0.8–1.0 N. This scenario would have created sufficient reciprocal forces for intrusion of the adjacent teeth, which would then cause a biomechanical side effect of additional flaring of the incisors (Fig. 7.5).
Space Creation
Expansion of the Arches Archwire expansion is biomechanically simple and is usually achieved quickly, as the desired tooth position is achieved by tipping of the teeth. However, this can lead to side effects in the vertical dimension that may require additional treatment for correction. Applying force labial to the center of resistance leads to proclination of the incisors during their relative intrusion (Fig. 7.6). Transverse expansion of the dental arches can be achieved by dental or skeletal means. In the maxilla, both options can be used on a regular basis due to the presence of the midpalatal suture. In the mandible, the structure equivalent to the maxillary midpalatal suture is the symphysis, which already ossifies before birth and can therefore not be expanded orthodontically. It can only be reopened after surgical intervention and expanded by means of osteogenic distraction.
a
As transverse dental expansion of the upper jaw usually encompasses buccal tipping of the posterior segments, “hanging palatal cusps” tend to result, which are often responsible for iatrogenic bite-opening (Fig. 7.7) and balancing interference. Dental or skeletal expansion? The treatment strategy should be determined by the primary characteristics of the malocclusion (Fig. 7.8). Treatment options for expansion are usually determined by the shape of the lower arch, as good coordination between upper and lower arches is required at the end of the orthodontic treatment. Dentoalveolar expansion is usually achieved by means of the archwire alone. Depending on the amount of expansion necessary, additional auxiliaries can be used, such as quad helices, expansion plates and “jockey wires,” to name but a few of the other types of expanders available today (Fig. 7.9). Significant transverse discrepancies are
Fig. 7.6a–d The anterior arch segment shows a lack of space, particularly for the canines. The incisors are retroclined and will be proclined during alignment. Due to the inclination of the canines, leveling and alignment using continuous-arch mechanics will lead to proclination and intrusion of the labial segment. Following alignment of the lower front teeth, the canines will eventually upright, but the lower incisors will maintain their proclined position.
b
Clinical pearl: “Stripping” from molar to molar and retracting anteriors (b)
c
d
a
b
c
e
f
d
Fig. 7.7a–f Particularly in the initial treatment phase, archwire expansion can lead to premature contacts between the palatal cusps of the maxillary molars. This may create an open bite that can lead to development of a lateral tongue thrust, which in turn can complicate the case and increase treatment time; correction of the buccal crown torque is only achieved with rectangular wires.
101
102
7
Treatment Dental expansion
– Archwire with partial fixed appliance – Archwire with full fixed appliances – Transpalatal arch – Bi-Helix, Quad-Helix – Small Slim-Line expander a
Skeletal expansion
Maxilla
Mandible
– RPE – Hybrid RPE – Surgically assisted hybrid RPE
Surgically assisted expander always required
b
Fig. 7.8a, b Expansion techniques using (a) dental expansion and (b) skeletal expansion. RPE, rapid palatal enlargement.
often best addressed by skeletal expansion (i.e., by expansion of the maxillary midpalatal suture; see also the section on “Space Creation by Expansion of Arches” below, p. 135). The presence of the midpalatal suture as well as the thin cortical structure of the maxillary bone are ideal for expansion of the upper jaw. This has to be viewed with the opposite situation in the lower jaw. For the latter, there is an abundance of compact buccal bone, and expansion is consequently more challenging even when surgical assistance is used.
a
b
Fig. 7.9a–c Dental expansion of the upper arch using palatal
expansion appliances. a A quad helix with a 2 × 4 appliance; this method is low-cost and effective, but the actual force levels are difficult to determine. The quad helix is made of stainless-steel wires, which can result in high force levels even after minor activations. It is often difficult to estimate the resulting forces, especially when activating the appliance intraorally.
Expansion with archwires. Adequate transverse development of the apical base is a prerequisite of archwire expansion (Fig. 7.10). In this particular example, a longstanding thumb-sucking habit had resulted in a V-shaped narrow upper jaw. However, the apical base was sufficiently wide to allow the use of a 2 × 4 appliance during the mixed dentition. The initial archwire was a 0.012 superelastic NiTi, which was followed by a 0.016 wire of the same material. The superelastic archwires were left in situ for 8 weeks each and resulted in a significant development in the arch form, both in the transverse as well as the anterior–posterior dimensions. For moderate expansion in the permanent dentition, we usually use a 0.012 or 0.016 archwire (for 8 weeks each). We subsequently use a 0.018 × 0.025 superelastic archwire, which fine-tunes the three-dimensional parameters. In cases in which ectopic teeth need to be aligned, this archwire sequence has to be modified; the sequential archwires are 0.010, and 0.012 to 0.016. Further expansion is usually achieved with rectangular archwires such as a 0.018 × 0.025 superelastic archwire. Expansion using an archwire is only of limited value in the lower arch (Fig. 7.11), as it really only allows buccal tipping of the posterior segments with correction of the curve of Wilson. The relatively dense bone structure of the mandible prevents skeletal expansion in the absence of surgical assistance—for example, in the form of osteogenic distraction (Fig. 7.12).
c
b, c We have found that the slimline expander (magnified view in c) works well, the force levels are more predictable. The patient typically activates the appliance a quarter turn every 3 days. A full turn of 360° results in 0.8 mm of expansion. This type of expander is better in terms of the applied force levels, although these are high at activation but still intermittent.
Space Creation
a
b
c
Fig. 7.10a–g An example of the effects of different archwire shapes on the arch form.
d
e
f
g
Fig. 7.11 Examples of expansion treat-
ment using an archwire. a, b Correction of minor irregularities and rotations by protrusion of the lower labial segment. Enamel reduction was performed from bicuspid to bicuspid.
a
b
103
104
7
Treatment
a
b
c
d
e
f
Fig. 7.12a–f Surgically assisted mandibular expansion (with a slimline screw). (d–f courtesy of Dr. Heinz Winsauer, Bregenz, Austria.)
Crowding and Ectopic Canines The following case studies are examples and illustrate “reduced-friction” full-arch treatments to resolve crowding of the anterior segments. Special emphasis is placed on the alignment of labially positioned maxillary canines. As with all treatment plans, it is important to have welldefined treatment aims before beginning fixed-appliance treatment. This includes the archwire sequence and material, with a view to treating the underlying occlusal discrepancies where present. This should include auxiliaries such as intramaxillary and/or intermaxillary elastics and other adjuncts such as interproximal enamel reduc-
tion. An alternative treatment option in cases of severe crowding should encompass the removal of teeth. It is generally thought that dental expansion of the arches is unstable, particularly because most of the alignment is often achieved by tipping movements of the teeth. However, modern retention techniques (see Chapter 9) make it possible to maintain orthodontic results over the longer term. From a scientific point of view, it should also be noted that there appears to be very little difference in the long-term stability of the alignment of the lower labial segment in particular between patients who are treated with an extraction approach or a nonextraction approach.15
Space Creation Case Study 7.1 (Fig. 7.13) Patient: A.-M.K., female, age 16. Diagnostic records: models, panoramic radiograph, lateral cephalometric radiograph, intraoral/extraoral photographs, low-dose CT. Main findings: moderate crowding in both jaws, transverse crowding, class II profile with mild retrognathia. Treatment aims: protrusion of the front teeth, leveling and expansion of the dental arches and improvement of the patient’s profile.
1
2
Appliances: self-ligating brackets, molar bands, occlusal stops, and interproximal enamel reduction. Archwire sequence: 0.012 SE, 0.016 SE, 0.018 × 0.025 SE, 0.019 × 0.025 SS, 0.021 × 0.025 SE. Alternative treatment strategy: extraction of first premolars. Active treatment time: 10 months. Retention: three-dimensional retention with Hawley retainers and bonded retainers.
3
Fig. 7.13 1–33 1–5 Initial presentation: constricted ma-
xilla with anterior crowding and blocked-out maxillary right canine. The mandible presents with moderate crowding. Molar and canine relationships are half-unit class II.
4
5
6
7
8
6–10 Full bonding with self-ligating
brackets and molar bands; a 0.012 superelastic NiTi archwire is fully ligated.
Clinical pearl: Occlusal stops allow distal disocclusion of teeth. The facial growth pattern and the temporomandibular joint need to be taken into consideration before the stops are applied.
9
10
105
106
7
11
Treatment
13
12
11–15 Treatment progress (0.018 × 0.025 superelastic archwires).
Errors and risks: Space creation in nonextraction treatment may have to include arch expansion as well as interproximal enamel reduction.
14
15
16
17
18
16–20 Final result: three-dimensional retention of both maxillary and mandibular teeth is necessary.
19
20
21 Low-dose computed tomography
shows that none of the teeth have been moved beyond their biological limit; no fenestrations or dehiscences are visible.
21
Space Creation 22–23 The stability of the sagittal ex-
pansion is limited. Approximal enamel reduction will create space for alignment and improved stability.
Errors and risks: Expansion in the sagittal plane (incisor proclination) is limited by its stability and periodontal concerns. Solution: interproximal enamel reduction (IPR). 22
23
24
25
26
28
29
27
24–29 Digital superimposition of the dental arches: initial presentation (images on the left and in red on virtual study models) compared with the result after 1 year in retention. Caution: Intercanine width was not changed in lower jaw (29)
30
31
32
33
30–33 The nasolabial angle improved concomitant with the protrusion of the upper labial segment as it became more acute. Nonextraction treatment improved facial harmony by supporting the position of the upper lip and subsequently reduced the nasal prominence.
107
108
7
Treatment
Case Study 7.2 (Fig. 7.14) Patient: M.K., male, age 14. Diagnostic records: models, panoramic radiograph, lateral cephalometric radiograph, intraoral/extraoral photographs. Main findings: severe crowding of the upper and lower arches, buccal placement of both upper canines with transverse crowding, and dental alveolar midline discrepancy in the lower jaw to the left.
1
2
Treatment aims: alignment of 13 and 33 by expansion, protrusion and interdental stripping, and correction of the midline discrepancy. Appliances: self-ligating brackets, molar bands, interproximal enamel reduction. Archwire sequence: 0.010 SE, 0.012 SE, 0.016 SE, 0.018 × 0.025 SE, 0.021 × 0.025 SE. Alternative treatment strategy: extraction of first premolars. Active treatment time: 11 months. Retention: three-dimensional retention with Hawley retainers and bonded retainers.
3
Fig. 7.14 1–23 1–5 Initial presentation: constricted ma-
xilla with bucally crowded teeth 13 and 23. The mandible presents with anterior crowding and a buccal 33, with marked deviation of the mandibular dental midline to the left.
4
5
6
7
8
6–10 Treatment progress, with fully li-
gated superelastic 0.016 round archwires.
9
10
Space Creation 11, 12 Caution: unrestricted proclination of the lower labial segment should be avoided. Tip: interproximal enamel reduction can limit the amount of incisor proclination.
11
12
CLINICAL PEARL 13–15 Does buccal expansion of the jaws result in fenestration of the buccal cortex?
13
14
15
Full-sized superelastic archwires such as 0.018 × 0.025 or 0.021 × 0.025 appear, within limits, to be able to transversally expand arches without substantial buccal bone loss. The three-dimensional computed-tomography reconstruction shows good buccal root coverage.
16–23 Clinical images and superimposi-
tion of the digital study models: initial presentation and final result after 1 year in retention. Retention was with removable appliances, which allowed slight tooth movement during the first year. Caution: Intercanine width was not changed (23)
16
17
18
19
20
21
22
23
109
110
7
Treatment
Case Study 7.3 (Fig. 7.15) Patient: B.C., male, age 15. Diagnostic records: models, panoramic radiograph, lateral cephalometric radiograph, intraoral/extraoral photographs. Main findings: transverse deficiency of maxilla, tendency to prognathia, buccal positioning of 13 and 23.
1
2
Treatment aims: expansion of the upper jaw, alignment of 13 and 23, reduction of the slightly increased overjet and overbite. Appliances: self-ligating brackets and molar bands. Archwire sequence: 0.012 SE, 0.016 SE, 0.016 × 0.022 SE, 0.018 × 0.025 SE, 0.019 × 0.025 SS. Active treatment time: 9 months. Retention: bonded retainers and three-dimensional retention in the upper jaw with a Hawley retainer.
3
Fig. 7.15 1–21 1–5 Initial presentation; buccally dis-
placed teeth 13 and 23 and a class III tendency in the buccal segments.
4
5
6
7
8
6–9 Initial alignment with a superelastic NiTi archwire 0.012, which was fully ligated.
9
CLINICAL PEARL A “stop” made of light-cured composite material can be used to avoid shifting of the archwires, which may cause patient discomfort.
Space Creation
10
11
12
10–14 0.019 × 0.022 stainless-steel
archwires with an elastomeric chain in the upper jaw.
13
14
15
16
17
15–19 One year in retention using a fixed retainer in the mandible and a removable retainer in the maxilla.
Errors and risks: Rapid, short treatments require careful retention.
18
19
20–21 The initial presentation and final
result after approximately 9 months of active treatment. (Images courtesy of Vittorio Cacciafesta, Milan, Italy.)
20
21
111
112
7
Treatment
Case Study 7.4 (Fig. 7.16) Patient: M.Y., female, age 15. Diagnostic records: models, panoramic radiograph, lateral cephalometric radiograph, intraoral/extraoral photographs. Main findings: anterior crowding, tipping of the occlusal plane.
1
2
Treatment aims: resolution of crowding and correction of the occlusal plane. Appliances: self-ligating brackets, molar bands and interproximal enamel reduction. Archwire sequence: 0.012 SE, 0.016 SE, 0.016 × 0.022 SE, 0.018 × 0.025 SE, 0.021 × 0.025 SE. Active treatment time: 8 months. Retention: fixed retention to the labial segments and further retention with vacuum-formed retainers.
3
Fig. 7.16 1–22 1–5 Initial presentation: class I with ma-
xillary and mandibular anterior crowding.
4
5
6
7
8
6–10 Self-ligating brackets with superelastic 0.012 NiTi wires in both arches.
Errors and risks: Limitation of incisor proclination by interproximal enamel reduction before placement of orthodontic appliances.
9
10
Space Creation
11
12
13
11–15 Leveling and alignment of the occlusal plane with square BioFinisher archwires.
14
15
16, 17
Clinical pearl: Taking the lateral cephalogram before the debonding appointment allows analysis of enamel to incisor inclination with the appliances still in place. It is still possible to improve it by means of interproximal enamel reduction or even dental extractions at this point.
16
17
18
19
20
18–22 One year after retention with vacuum-formed retainers. Errors and risks: Stability: fixed retention should be considered if the patient’s compliance with retainer wear is expected to be poor.
21
22
113
114
7
Treatment
Case Study 7.5 (Fig. 7.17) Patient: A.B., male, age 17. Diagnostic records: models, panoramic radiograph, lateral cephalometric radiograph, intraoral/extraoral photographs. Main findings: asymmetric buccal segment relationship, crowding of the upper front teeth.
Treatment aims: alignment of the upper front teeth only (the patient requested limited treatment), including interproximal size reduction (stripping). Appliances: self-ligating brackets, approximal enamel reduction. Archwire sequence: 0.012 SE, 0.016 SE, 0.016 × 0.022 SE, 0.018 × 0.025 SE 0.021 × 0.025 SE. Alternative treatment strategy: lingual fixed appliance. Retention: fixed retainer to the upper front teeth.
Fig. 7.17 1–17 1 Crowding of the anterior teeth, parti-
cularly of the central incisors, was the patient’s chief complaint.
1
2
3
4 2–6
Caution: Retroclination of 11 (upper right central incisor) limits extrusion and proclination of the lower labial segment and it may potentially restrict mandibular excursions, also holding the mandible in a class II situation.
5
6
7
8
9
7–9 Following placement of 0.012 and 0.016 superelastic NiTi archwires, torque values are improved by using square superelastic wires.
CLINICAL PEARLS • Composite stops palatal to the upper central incisors. • Interproximal enamel reduction before archwire placement.
Space Creation CLINICAL PEARL The fixed retainer is only fitted to the upper incisors. The canines have not been bonded, in order to avoid occlusal contact between the retainer and the lower teeth, which could lead to higher failure rates. 10–13 0.021 × 0.025 superelastic NiTi archwire and subsequent retention.
10
11
12
13
14–17 The initial presentation and the
treatment result after 1 year in retention (right-hand side). (Treatment and images courtesy of Vittorio Cacciafesta, Milan, Italy.)
14
15
16
17
115
116
7
Treatment
Case Study 7.6 (Fig. 7.18) Patient: J.J., male, age 9. Diagnostic records: models, panoramic radiograph, lateral cephalometric radiograph, intraoral/extraoral photographs. Main findings: distal displacement of the lower jaw due to excessive retroclination of the upper labial segment (Class II/2 occlusion), deep traumatic overbite, and anterior crowding. Treatment aims: resolve posterior displacement by protrusion and expansion of the upper jaw.
Appliances: self-ligating brackets, molar bands (2 × 4 appliance). Archwire sequence: 0.012 SE, 0.016 SE, 0.016 × 0.022 SE, 0.019 × 0.025 SS. Alternative treatment strategy: removal of appliances with expansion plate to the upper jaw and protrusion springs for the upper labial segment. Active treatment time: 7 months. Retention: three-dimensional retention using an upper removable appliance or functional appliance to potentially avoid more complex treatment in the teenage years.
1
2
3
4
5
6
7
8
9
Fig. 7.18 1–9 1–9 Class II/2 occlusion, with severely retroclined and overerupted
central incisors. Left column: before treatment.
CLINICAL PEARL The 2 × 4 fixed appliance is often a good alternative to removable appliances, as it is not dependent on patient compliance. Early alignment, particularly of the upper front teeth, can lead to spontaneous correction of a class II molar relationship, as seen in Fig. 7.18.
Middle column: 0.012 superelastic NiTi archwires ligated. Right column: after correction of the maxillary incisor angulation, the mandible is free to develop in a forward direction.
Treatment of Occlusion after Leveling and Alignment It is often noticed that occlusal interference persists after the leveling and alignment stage. It can be eliminated by using harmonized arch shapes. After good coordination between the dental arches has been established, spontaneous improvement of the occlusion often occurs without any need for extensive intermaxillary elastic wear (see Case Studies 7.7–7.9).
Space Creation Case Study 7.7 (Fig. 7.19) Patient: M.K., female, age 15. Diagnostic records: models, panoramic radiograph, lateral cephalometric radiograph, intraoral/extraoral photographs. Main findings: crowding of 13 and 43, open bite tendency with tongue interposition in the area of 13, 43 and 23, 33. Treatment aims: align 13 and 43 and secure the reduced overbite.
1
2
Appliances: self-ligating brackets, molar bands, approximal enamel reduction, intermaxillary elastics. Archwire sequence: 0.012 SE, 0.16 SS, 0.016 × 0.022 TMA, 0.018 × 0.025 SE, 0.019 × 0.025 SS. Alternative treatment strategy: extraction of premolars. Active treatment time: 12 months. Retention: bonded retainers to upper and lower front teeth and follow-up of the overbite situation with monitoring of growth.
3
Fig. 7.19 1–28 1–5 Initial presentation: there is crow-
ding in both arches but a normal buccal segment relationship, with reduced overbite and overjet.
4
5
6
7
8
6–10 0.012 superelastic NiTi archwires fully ligated to all brackets. Note: Full ligation into all teeth can cause an anterior open bite, and subsequent interposition of the tongue between the teeth should be monitored carefully. IPR should be considered at the start of treatment.
9
10
117
118
7
Treatment
11
12
13
11–15 A 0.016 × 0.022 titanium–molyb-
denum alloy (TMA) archwire with extrusion bends for the anterior segments.
Caution: Inclination problem! Enamel reduction in the lower jaw from 5–5 and in the upper premolars must be performed.
14
15
CLINICAL PEARL Question: How should the overbite be preserved? Answer: • Apply vertical elastics to the maxillary canines. • Do not bond the second molars. • Interproximal enamel reduction and retroclination of the incisors. 16
17
18
19
17–21 Interproximal enamel reduction
of the maxillary incisors was carried out; there is significant stripping of the lower labial segment, with subsequent retroclination of the teeth. Segmental archwires can be used to improve settling.
20
21
CLINICAL PEARL Space for retroclination of the anterior segment is created by interproximal reduction, and the labial segments are retroclined by subsequent use of a continuous elastic chain.
Space Creation
22
23
24
22–26 Result after 1 year in retention.
25
26
27, 28 Lower incisor inclination at the
start of treatment and following orthodontic treatment; lip competence at end of treatment.
Errors and risks:
27
28
Incisor inclination was preserved despite the initial crowding. However, fixed retention should be considered in borderline nonextraction cases. The development of the third molar should be monitored during the follow-up.
CLINICAL PEARL
1
2
Fig. 7.20
1, 2 Delayed or ectopically erupting canines can be corrected using a superelastic overlay wire (piggyback technique). Other teeth can still be moved on the rigid base arch. Using self-ligating brackets with an auxiliary slot can be beneficial, as shown here.
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Treatment
Case Study 7.8 (Fig. 7.21) Patient: A.N., female, age 15. Diagnostic records: models, panoramic radiograph, lateral cephalometric radiograph, intraoral/extraoral photographs. Main findings: increased overjet, anterior crowding, and rotations. Treatment aims: coordination of the arches, alignment of the upper and lower labial segments, and reduction of the overjet.
1
2
Appliances: self-ligating brackets, molar bands, approximal enamel reduction. Archwire sequence: 0.012 SE, 0.016 SE, 0.016 × 0.022 SE, 0.018 × 0.025 SE, 0.021 × 0.025 SE. Alternative treatment strategy: n/a. Active treatment time: 12 months. Retention: three-dimensional retention, including bonded retainers.
3
Fig. 7.21 1–22 1–5 Initial presentation: maxillary and
mandibular crowding combined with a constricted maxillary arch. Class II tendency.
4
5
6
7
8 6–10
Clinical pearl: The retroclined maxillary left incisor is restricting mandibular excursions.
9
10
Space Creation
11
12
13
11–15 Alignment of the upper and lower arches leads to spontaneous correction of the initial class II discrepancy. Errors and risks: Self-ligating brackets may also require individual finishing bends in the later stages of treatment.
14
15
16, 17 Clinical pearl: Comparison of lateral cephalograms before treatment and before appliance removal makes it possible to assess the incisor angulation. Adjustments of incisor inclinations are still possible using interproximal reduction and continuous elastic chains, as the appliances are still in place. Uppers need additional torque in this case to allow a mandible class I.
16
17
18
19
20
18–22 The final result after 1 year of
retention using fixed retainers combined with Hawley retainers.
21
22
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Treatment
Case Study 7.9 (Fig. 7.22) Patient: K.H., female, age 15. Diagnostic records: models, panoramic radiograph, lateral cephalometric radiograph, intraoral/extraoral photographs. Main findings: bilateral crossbite, open bite in the premolar areas affecting the left more than the right, tendency to mandibular prognathism. Treatment aims: expansion in the upper jaw and establishment of good intercuspation.
1
2
Appliances: self-ligating bracket, molar bands, approximal enamel reduction in the lower jaw. Archwire sequence: 0.012 SE, 0.016 SE, 0.016 × 0.022 SE, 0.018 × 0.025 SE, 0.019 × 0.025 SS. Alternative treatment strategy: rapid maxillary expansion. Active treatment time: 11 months. Retention: maintenance of the alignment with bonded retainers with additional three-dimensional retention in the upper jaw.
3
Fig. 7.22 1–5 Initial presentation: anterior crow-
ding with a constricted maxilla and bilateral crossbite.
4
5
Space Creation 7–11 The final result after 1 year of retention with anterior fixed retainers combined with Hawley retainers.
7
8
9
10
11
12
13
14
12–18 Comparison of the pretreatment
and post-treatment situation intraorally, cephalometrically, and by superimposition of the digital study models of the maxilla. Superimposition of the study models shows that very little actual expansion was necessary to correct the bilateral crossbite.
15
16
Errors and risks: The mandibular prominence increased within 2 years.
17
18
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Treatment
Space Creation by Distalization Most conventional distalizers use the anterior dentition and the palate as the retentive element for distalizing the posterior teeth. This was first described by Hilgers in 1992.13,14 The pendulum appliance showed a distalization of 63.5%–73.5% and reciprocal mesial protrusion of the anchorage teeth in the anterior segment between 26.5% and 36.5%.4,9,18 In addition, there was distal tipping of the molars between 10.6° and 18.5°.4,9 A simplified distalizer known as a Frog appliance was first described by Walde. It is also known as a “simplified molar distalizer” (Fig. 7.23).32 The basic design features (Fig. 7.24) consist of a custom screw, which is connected to the first molars via a transpalatal arch. This element is anchored by an acrylic (Nance-type) button, which itself is cemented to the first and second premolars via wire extensions. The transpalatal arch is designed in such a way that it can be removed, modified, and activated. It can also be left in place once the distalization components have been removed. Walde recommended one activation every 4–5 weeks, with a total of approximately five turns, which results in molar distalization of 1–2 mm every month. The screw has been designed in such a way that a full turn distalizes the elements by half a millimeter. The authors recommend one turn (a quarter of 360°) every 3 days. A more efficient way of using the Frog device relies on skeletal anchorage of the mesial aspect, by measures of orthodontic mini-implants. The anterior palate is an ideal place for secure placement of mini-implants. The ideal insertion point is mesial to the
Fig. 7.23 The Frog appliance (Forestadent), with a combination of tooth-borne and tissue-borne anchorage.
connecting point between the two upper first premolars (this point has been chosen as it is often easily identifiable due to the nonerupted canines at the start of treatment), 4.5 mm behind the distal aspect of the incisal papilla (Figs. 7.25 and 7.26).10,11,35 The ideal transverse distance to the midpalatal suture is approximately 3 mm on either side, as this has the best bone tissue available for secure placement.35 The skeletal anchorage and sectional wire approach allows orthodontic treatment mesially to the second premolars during distalization of the posterior segments, which can decrease the overall treatment time—particularly in comparison with the original design of this distalization device, which required orthodontic treatment in several stages. The first-generation skeletal Frog still used an acrylic button in which the mini-implants were anchored. Although it was effective, it had the familiar disadvantage of restricted oral hygiene, with subsequent irritation and inflammation of the gingiva. This led to the development of the skeletal Frog without the acrylic button, in which an abutment directly connects the mini-implants to the distalizing screw. Further refinements of the design led to an abutment that is compatible with the Ortho-Easy system, which doubles as a transfer aid and coupling unit (Fig. 7.27). The steps required to fabricate the appliance are as follows: after insertion of the implants, the abutments are mounted on the heads of the mini-implants and an impression is taken. “Transfer implants” are then attached to the abutments before pouring of the impression. This creates a model containing two implant heads that correspond to the situation in the patient. The abutments are then replaced on the implants and are integrated into the final appliance by soldering or laser-welding them to the screw–transpalatal arch complex (Fig. 7.28). The abutment is first tried-in to make sure that the fit is adequate. A diverging insertion in the direction of the abutments may become necessary in case the mini-implants are not completely parallel. The abutments may then need modification so that they can be inserted without interference. Once the abutments have been tested and found to give a satisfactory fit, glass ionomer cement can be used to securely fasten the distal component of the Frog appliance, while the abutments are secured with a flowable composite (Fig. 7.28). The small size of the abutments allows good cleaning of the palatal mucosa, as well as reduced interference of the Frog appliance with the tongue, particularly compared to the traditional design using an acrylic button.
Space Creation
a
b
c
d
e
Fig. 7.24a–e The Frog appliance (Forestadent) consists of several
prefabricated parts, which are assembled in a laboratory. The parts include a distalization screw, a prefabricated transpalatal arch made of 0.032 stainless steel, and a key for activating the distalizing screw. The connection between the transpalatal arch and the distalizing
screw is removable (a–c). Activation occurs at the anterior part of the screw, so the key can be inserted sagittally. The easy access makes activation simple and helps ensure good patient compliance (d, e).
Fig. 7.25a, b Mini-implants should be
a
b
inserted mesial to the line connecting the two upper first premolars. This appears to be a stable position with sufficient bone for secure retention of the Frog appliance (Forestadent). It can sometimes be difficult to locate this point due to mesially migrated premolars or previous extractions. Another anatomical landmark that can be used to position the mini-implants is a point 4–5 mm distal to the posterior end of the incisal foramen.
Fig. 7.26a, b a Computed tomography of positioned
mini-implants that have been inserted perpendicular to the palatal surface. b The frontal view shows the amount of bone available for anchorage.
a
b
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Treatment
a
b
c
Fig. 7.27a–c The Ortho Easy system (Forestadent). a View of the abutment from both sides (top and bottom).
a
b
b Lateral view. The abutment has a built-in undercut. c Precise fitting of the abutment to the mini-implant head.
c
d
Fig. 7.28a–j a The mini-implant has been placed in the patient’s mouth. b The circular undercut ensures good retention in the impression material (c) and secure repositioning of the transfer screws (d). Now the
impression can be cast in high-strength (type 4) dental stone. e–j See p. 127.
Space Creation
e
f
g
h
i
j
Fig. 7.28a–j (continued) e, f The manufacturing process for the skeletal K-pendulum. e The working model made of high-strength (type 4) dental stone,
with the transfer screws. f Abutments on the transfer screws and molar bands are in place. g Positioning of the Frog screw with correct angulation, which allows the activation key to fit.
h Completed laboratory work after soldering of the abutments to the distalizing screw.
i Fitting of the titanium–molybdenum alloy (TMA) transpalatal arch. j The all-metal framework of the K-pendulum allows good oral hygiene.
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Treatment
Case Study 7.10 (Fig. 7.29) Patient: S.W., female, age 11. Diagnostic records: models, panoramic radiograph, lateral cephalometric radiograph, intraoral/extraoral photographs. Main findings: crowding of 13 and 23 buccally. Treatment aims: distalizing the upper molars to create space for alignment of 13 and 23.
1
2
Appliances: self-ligating brackets, molar bands, miniimplants, Frog appliance. Archwire sequence: 0.012 SE, 0.016 SE, 0.016 × 0.022 SE, 0.018 × 0.025 SE, 0.019 × 0.025 SS. Alternative treatment strategy: removal of premolars in the upper jaw. Active treatment time: 12 months. Retention: three-dimensional retention with Hawley retainers.
3
Fig. 7.29 1–31 1–5 Initial presentation: blocked-out ma-
xillary canines and mild anterior mandibular crowding.
4
5
6
7
8 6–10
Clinical pearl: The Frog appliance is activated immediately after insertion by four to five turns.
9
10
ERRORS AND RISKS The maxillary archwire extends only to the second bicuspids.
Caution: If the first molars are included in the continuous archwire, the distally directed force can lead to undesired retroclination of the incisors.
Space Creation
11
12
13
11–15 The results of distalization 5
months into treatment, with overcorrection of the maxillary molars.
14
15
16
17
18
16–20 Ten months into treatment, the occlusion has been corrected.
19
20
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Treatment
21
22
23
21–25 The start of the retention phase, with removable retainers.
24
25
26
27
28
26–28 Lateral cephalometric radiographs before treatment, after distalization, and post-treatment.
30
29
31
32
29–32 Distalization of the first molars: comparison of the situation before treatment and after 1 year of retention: superimposition of the digital study models.
ERRORS AND RISKS Does the skeletal Frog appliance prevent protrusion of the labial segments?
This case report suggests that incisor angulation remains largely unchanged (see Fig. 7.29, 26–28 and 29–32).
Space Creation Case Study 7.11 (Fig. 7.30) Patient: A.P., female, age 11. Diagnostic records: models, panoramic radiograph, lateral cephalometric radiograph, intraoral/extraoral photographs. Main findings: crowding of 13 and 23. Treatment aims: distalizing of the molars to create space in the maxillary canine area.
1
2
Appliances: self-ligating brackets, molar bands, miniimplant, Frog appliance. Archwire sequence: 0.012 SE, 0.016 SE, 0.016 × 0.022 SE, 0.018 × 0.025 SE, 0.019 × 0.022 SS. Alternative treatment strategy: extraction of the first premolars in the upper jaw. Active treatment time: 10 months. Retention: three-dimensional retention with Hawley retainers.
3
Fig. 7.30 1–24 1–5 Initial presentation: buccally crowd-
ed maxillary canines and mild anterior mandibular crowding.
4
5
6
7
8
6–10 Treatment progress: alignment and distalization.
Errors and risks: The maxillary archwire extends only to the second bicuspids. If the first molars are included, retroclination of the upper front tooth may result.
9
10
131
132
7
Treatment 11 Before treatment. 12 Placement of mini-screws and self-
ligating brackets. 13 The Frog appliance has been active for 5 months. 14 End of distalization.
11
12
13
14
15
16
17
15–19 After approximately 10 months, good alignment, molar and canine relationship has been achieved.
18
19
CLINICAL PEARL Ectopically positioned teeth, particularly canines, may show an esthetically compromised gingival margin after alignment (circled in 15). Using an electric toothbrush
with a soft head may be advisable, as it can help protect the gingival tissues. A gingival graft can be considered for correction.
Space Creation
20
21
22
20–24 Start of retention with removable retainers.
23
24
Fig. 7.31 The skeletally supported Frog appliance at the end of the distalization phase. The molars have tipped distally and are rotated due to biomechanical side effects. This can be corrected after distalization.
The design of the original Frog appliance used a transpalatal arch made of stainless steel. The design did not allow correction of previously rotated molars or iatrogenic distal tipping (Fig. 7.31), and it was therefore replaced in second-generation appliances with a round 0.032 titanium–molybdenum alloy (TMA). This is similar to the approach used in the K-pendulum (Kinzinger). This transpalatal arch is designed with loops that can be adjusted to derotate teeth, expand the archwire, or counteract the distal tipping movement that normally occurs during distalization (Fig. 7.32). Several investigations of the force levels provided by the TMA transpalatal arch have shown that its initial activation and periodic reactivation can lead to effective control of the side effects occurring during molar distalization. The tendency for maxillary constriction that results from activation of the screw can also be counteracted by expansion of the transpalatal arch. In other words, the reactivation of the modified Frog appliance is similar to that of the K-pendulum, the effects of which have been well investigated. The Frog appliance is therefore also known as a skeletal K-pendulum.18 Figure 7.33 illustrates the position of the pendulum springs resulting from bending and activation.
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Treatment
Fv a
WZ -Mp Fv
Fti -Fp
-Fp
WZ M
FE
Mp
MA
-FA
FK c
b
Fig. 7.32a–d Activating the components of the pendulum ap-
pliance. a, b Toe-in bend of the transpalatal arch for derotation.
d
c, d Uprighting activation to counteract the distal crown tip on the molars.
Fig. 7.33a–d a At the start of distalization. b After 3 months, with significant rotation
of the molars (too little “toe-in” of the transpalatal arch). c Extraoral reactivation to increase the “toein.” d At follow-up examination 8 weeks later shows an improved molar position.
a
b
c
d
Space Creation the first premolars. It is important that the implants should not be inserted too close to the median suture, otherwise the stability of the implants may be compromised during expansion (Fig. 7.34). We recommend activating the expansion screw three times a day (Figs. 7.34 and 7.35). The fabrication of the expansion device is similar to that described for the Frog appliance. The abutments are filled with Vaseline and placed over the mini-implant heads, and an alginate impression is taken. The rapid maxillary expansion device is subsequently fixed to the mini-implants in the anterior palate and to the first molars in the posterior palate via the abutments, which also double as coupling devices (Fig. 7.36). The advantage of the bone-borne expansion approach in the anterior maxilla lies in the application of forces directly onto the skeletal structures in that area; the dentition is not affected. This allows more efficient expansion of the midpalatal suture, with potentially fewer dental
Space Creation by Expansion of Arches Skeletal expansion of the upper jaw by expanding the midpalatal suture was first described by Angelle in 1860, but this form of treatment only gained wider acceptance after 1953, mainly inspired by the work of Derichsweiler and Korkhaus. Conventional rapid maxillary expansion uses forced expansion of the midpalatal suture by fourpoint retention, usually on the first molars and the first premolars. Modifications of this device involving a bonded expander design rely on acrylic capping of the posterior segments. The present authors prefer a combined tooth-borne/bone-borne anchorage solution. This hybrid maxillary expander replaces the premolar bands with mini-implants.34 Insertion of the mini-implants is similar to the method described in section on “Space Creation through Distalization� above (Fig. 7.34). The screws are inserted roughly 2 mm paramedian to the suture and on a line connecting the mesial aspects of
a
b
c
Fig. 7.34a–c The mini-implants are placed on a line mesial to the two upper first premolars, 4 mm distal to the incisive papilla. The implants should be inserted approximately 2 mm lateral to the maxillary suture.
a
b
Fig. 7.35a, b Three-dimensional computed-tomography images. Immediately after expansion of the maxilla, the midline suture opens.
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Treatment
a
b
c
d
e
f
Fig. 7.36a–f The laboratory procedure for hybrid rapid palatal
expansion (RPE). a Fixation of the abutments. b, c Seating of the expansion screw. The frontal arms are shortened and welded to the abutments. The posterior arms are adapted to fit the molar bands and are also welded.
side effects. An additional advantage is that orthodontic treatment mesial to the upper first molars can be carried out simultaneously (such as leveling and alignment) and archwire progression is possible during the retention period. The final 0.019 Ă— 0.025 stainless-steel archwires can then be used to maintain the transverse changes without the need to keep the expansion device in place for long periods of time (Fig. 7.37). This approach allows more efficient overall treatment (one phase instead of two phases). This hybrid maxillary expansion device is suitable for patients in the mixed permanent dentition period, as well as adults. It is now widely known that the midpalatal suture does not completely fuse, so even adults can be treated in this way. The increased difficulty of maxillary expansion in the upper jaw in adults is mainly thought to be due to solidification of the lateral skeletal structures of the skull, such as the maxillary abutment of the zygoma, rather than to solidification of the midmaxillary suture.20,31,38 In patients over the age of 25, we recommend a cut in the zygomatic structures of the lateral maxilla (rather than a complete osteotomy) to aid maxillary expansion.
d The completed hybrid RPE. e, f An example of a safety screw (Snap Lock, Forestadent). After
each activation, a leaf spring engages the screw and prevents it from inadvertently turning backward.
Space Creation
a
b
d
e
f
g
c
h
Fig. 7.37a–h A clinical example of maxillary expansion using hybrid rapid palatal expansion (RPE) (a–e). The skeletal effect is
clearly visible on the intraoral photographs; the abutments are
spread apart (a–c). Radiographs confirm this (d, e). f–h Surgically assisted hybrid RPE in a 45-year-old man.
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Treatment
Case Study 7.12 (Fig. 7.38) Patient: N.H., male, age 8. Diagnostic records: models, panoramic radiograph, lateral cephalometric radiograph, intraoral/extraoral photographs. Main findings: bilateral crossbite, reduced overjet, and overbite. Treatment aims: forced expansion of the upper jaw, alignment of both upper and lower front teeth.
1
2
Appliances: self-ligating brackets, molar bands, mini-implants, hybrid rapid maxillary expander. Archwire sequence: 0.012 SE, 0.016 SE, 0.016 × 0.022 SS: after eruption of 22 0.012 SE, 0.016 SE, 0.017 × 0.025 SE. Alternative treatment strategy: conventional rapid maxillary expansion. Active treatment time: 10 months (including waiting for eruption of 22). Retention: upper and lower retainers, with a midline screw to allow for expansion if necessary.
3
Fig. 7.38 1–18 1–5 Initial presentation: bilateral cross-
bite with a constricted maxilla in the mixed dentition.
4
5
6
7
8
6–8 Mini-implants placed and self-ligating brackets in place (6), hybrid rapid maxillary expander inserted (7), and the appliance after 2 weeks of expansion (8).
Space Creation
9
10
11
9–11 The site of the hybrid expander immediately after removal and 1 year after retention.
12
13
14
12–14 After 10 months of interceptive treatment.
15, 16 Posteroanterior cephalograms
before expansion and immediately after expansion.
15
16
CLINICAL PEARL Question: Does the skeletal anchorage of the hybrid rapid maxillary expander prevent buccal tipping of the molars used for retention?
Answer: In addition to confirming the sutural effects, analysis of the frontal cephalogram shows that the position of the anchoring molars is largely stable.
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Treatment 17, 18 Before treatment and 1 year after completion of interceptive treatment, with occlusal relationships appropriate for the patient’s age.
17
18
ERRORS AND RISKS
1
Fig. 7.39
1–3
2
3
1–3 In the mixed-dentition phase, premature occlusal contacts between the deciduous teeth may lead to a functional shift in the mandible. These contacts should be eliminated at an early stage by simple occlusal adjustment.
Space Creation Case Study 7.13 (Fig. 7.40) Patient: J.L., female, age 13. Diagnostic records: models, panoramic radiograph, lateral cephalometric radiograph, intraoral/extraoral photographs. Main findings: skeletal class III with maxillary hyperplasia and blocked out of 13, reduced overjet, and open bite tendency. Treatment aims: skeletal expansion of the upper jaw, space creation in the area of 13, and improvement of the overjet and overbite.
1
Appliances: self-ligating brackets, molar bands, mini-implants, hybrid rapid maxillary expansion. Archwire sequence: 0.012 SE, 0.016 SS, 0.016 × 0.022 SE, 0.018 × 0.025 SE, 0.019 × 0.025 SS. Alternative treatment strategy: conventional rapid maxillary expansion. Active treatment time: 13 months. Retention: three-dimensional retention encompassing a removable retainer with the potential for further expansion (midline screw).
2
3
Fig. 7.40 1–21 1–5 The initial presentation: constricted
maxilla, unilateral crossbite (left); tooth 13 is blocked out buccally.
Errors and risks: Maxillary constriction causing a functional shift to the left creating a unilateral crossbite.
4
5
6
7
8
6–8 Simultaneous use of a hybrid rapid palatal expander and self-ligating brackets for transverse expansion in the upper jaw.
9
10
9, 10 After 10 days of activation of the hybrid rapid palatal expander (the archwire has been cut in the midline).
11
11 3.5 months into treatment.
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7
Treatment ERRORS AND RISKS The maxillary archwire should be sectioned between the maxillary central incisors before expansion.
CLINICAL PEARL Settling of the occlusion using vertical elastics to the canines.
12
13
14
12–14 The maxillary anterior segment is stepped down and the mandibular anterior segment is stepped to increase the overbite. Vertical triangular elastics are worn for further support.
15
16
17
15–19 The situation before debonding.
18
19
20, 21 The midline discrepancy was re-
solved by expansion of the upper jaw and correction of the crossbite.
20
21
Space Creation by Extracting Teeth Extraction in the permanent dentition is one of the oldest, quickest, easiest, and most predictable ways of creating space. Holinder and also Herbst recommended extracting premolars routinely to create space in orthodontics as early as 1882. Removing a single premolar creates about 7–8 mm of space, and symmetrical extraction of two
premolars will create approximately 16 mm of space. In a large number of patients, this is more space than is actually required to align the teeth. In select cases, however, extractions are beneficial and necessary. The most common reason for removing premolars in our practice is to correct primary or secondary crowding and for camouflage treatment of underlying skeletal base discrepancies that do not warrant a surgical approach.
Space Creation Case Study 7.14 (Fig. 7.41) Patient: J.F., female, age 14. Diagnostic records: models, panoramic radiograph, lateral cephalometric radiograph, intraoral/extraoral photographs. Main findings: crowding, with all four canines blocked out labially. Treatment aims: Extraction of all four first premolars, alignment of all teeth.
1
2
Appliances: Self-ligating brackets, molar bands. Archwire sequence: 0.012 SE, 0.016 SE, 0.016 × 0.022 SE, 0.021 × 0.025 SE, 0.019 × 0.025 SS for sliding mechanics. Alternative treatment strategy: skeletally anchored Frog appliance, interproximal reduction for mandibular space creation. Active treatment time: 13 months. Retention: three-dimensional retention.
3
Fig. 7.41 1–18 1–5 The findings before treatment: significant crowding in both dental arches.
4
5
6
7
8
6–10 0.012 SE archwires and self-ligating brackets placed in the maxillary arch. Clinical pearl: There is immediate tooth movement into a fresh extraction socket. The dental surgeon should be asked not to compress the alveolus after the extraction, to avoid constriction of the site.
9
10
143
144
7
11
Treatment
12
13
11–15 0.021 × 0.025 SE archwires. Clinical pearl:
14
15
16
17
In patients with crowding, the combination of square superelastic wires and a low-friction environment allows teeth adjacent to an extraction site to gently migrate into the site, often without the use of space-closing adjuncts such as elastics.
18
16–18 Before treatment, maxillary appliances, final result. (Images courtesy of Dr. Javier Frenck, Cordoba, Argentina.)
Space Creation Case Study 7.15 (Fig. 7.42) Patient: A.H., female, age 12. Diagnostic records: Models, panoramic radiograph, lateral cephalometric radiograph, intraoral/extraoral photographs. Main findings: maxillary prognathism with proclined maxillary incisors; moderately retrognathic mandible on cephalometry.
1
2
Treatment aims: extraction of maxillary first premolars, anterior retraction (camouflage treatment). Appliances: self-ligating brackets, molar bands. Archwire sequence: 0.012 SE, 0.016 SE, 0.016 SS, 0.016 × 0.022 SE, 0.018 × 0.025 SE, 0.019 × 0.025 SS. Alternative treatment strategy: distalization, Herbst appliance, orthognathic surgery after completion of growth. Active retention time: 14 months. Retention: three-dimensional retention with a Hawley retainer.
3
Fig. 7.42 1–30 1–5 The situation before treatment, with
increased overjet (12 mm) due to maxillary prognathism and only moderate mandibular retrognathism.
4
5
CLINICAL PEARL • Attention should be paid to the patient’s habits and habitual positioning of the lower lip. • Orthodontic camouflage should be considered as a valid alternative. • The advantages and disadvantages of the different treatment options need to be explained to the patient.
6
7
8
6–10 0.012 SE archwires with self-ligating brackets. Clinical pearl: The premolars that will be extracted are not bonded, so space closure can occur immediately after extraction.
9
10
145
146
7
Treatment ERRORS AND RISKS Action is equal and opposite to reaction, so that anchorage loss may occur. Mesialization of the posterior segments needs to be avoided to allow for en-masse retraction of the anterior teeth. Strategies:
11
12
11 Skeletally anchored transpalatal arch.
13
14
12, 13 Buccal mini-implant with a power
14 Class II elastics (1⁄4 6 oz) for sliding
arm.
mechanics.
Predictable ¾¾¾¾¾¾¾¾¾¾¾¾¾¾¾¾¾¾¾¾¾¾¾¾¾¾¾¾¾¾¾¾¾¾¾¾¾® Unpredictable
15
16
17
15–19 A mild class III canine relationship, with residual space closure still to follow.
18
19
Space Creation
20
21
22
20–24 After 1 year of retention with a removable mandibular advancement appliance.
23
24
25–30 Comparison of the situation be-
fore and after treatment: extraoral photographs, cephalometric radiographs, and intraoral photographs.
25
26
27
28
29
30
147
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Treatment NOTE The decision on whether to carry out camouflage treatment for an underlying skeletal base discrepancy (such as the removal of the upper first premolars to compensate for a class II skeletal base) depends on cephalometric analysis including soft and hard tissues, patient preferences and medical history. In Case Study 7.15, maxillary prognathism rather than mandibular deficiency was diagnosed. We felt that surgical correction by bringing the lower jaw forward was not indicated. The soft-tissue profile before treatment shows incompetent lips. Before treatment the patient was unable to close her mouth even with pronounced lip straining. The retrusion of the maxillary anterior segment and simultaneous proclination of the mandibular anterior segment led to a very favorable soft-tissue response, with an improvement in the facial profile and competent lips as the final result.
In cases in which premolars have been extracted and space closure follows, a low friction bracket system can be extremely useful. It allows more efficient space closure and retraction of the anterior segment via sliding mechanics. Another option in these cases is to combine active self-ligating brackets in the anterior segment (for improved torque control) and passive self-ligating brackets in the posterior segments for reduced friction. While this will maintain or improve incisor torque, it allows controlled sliding mechanics at reduced force levels, which prevents side effects such as bowing of the archwire.
Space Creation by Interproximal Enamel Reduction (IPR) Interproximal enamel reduction (IPR or stripping) is a recognized alternative to extraction of teeth in selected cases. The space created for the anterior segments can be between 4 mm and 9 mm per arch.12,37 According to Fillion, maxillary incisors can be reduced by approximately 0.3 mm for each contact and mandibular incisors by approximately 0.2 mm. Buccal teeth can generally be reduced by 0.6 mm.8 Sheridan showed that an overall space gain of nearly 6.5 mm can be achieved on a regular basis.28,29 Reduction of the enamel by about 50% of its original thickness is considered acceptable and does not create longterm problems. This would theoretically allow for more than 9 mm of space to be created in each arch.30 Neither increased sensitivity of the teeth nor greater susceptibility to developing dental caries has been demonstrated in longterm follow-up studies of patients who underwent this form of treatment. In fact, some authors reported that 10 years after orthodontic treatment with IPR, the irregularity index compared favorably with patients who had undergone orthodontic treatment without IPR.36 The clinical
procedure is described in the section on “Interproximal Enamel Reduction (Stripping)” in Chapter 8.
Correction of Skeletal Discrepancies Correction of a Class II Buccal Segment Relationship Based on the findings by Roux that functional occlusal stimuli affect the growth of the maxilla and mandible, Andreesen and Häupl introduced the now-classical concept of functional orthodontics in 1935. Most of the functional appliances were originally removable, and patient compliance was an issue. Adequate wearing time is of paramount importance for achieving the treatment aims, and this issue led to the development of the noncompliance myofunctional systems that are now routinely used in many orthodontic practices. It was the rediscovery of the “Herbst appliance” (originally dating from 1904) by Pancherz in the 1970s that led the way to noncompliance class II correctors during the past 20 years. Other examples of noncompliance functional appliances are the Mandibular Anterior Repositioning Appliance (MARA), the Functional Mandibular Advancer (FMA), and other successors to the Herbst appliance such as the Sabbagh Universal Spring (SUS) and the Forsus spring. All of these appliances have been used successfully, and they have been extensively described in the literature. Apart from the very effective therapeutic principles, all noncompliance functional appliances can also demonstrate unwanted side effects such as significant proclination of the lower incisors. This is a well-known unwanted side effect that is particularly prevalent with use of Herbst appliances.
Functional Mandibular Advancer The Functional Mandibular Advancer (FMA) was developed by Kinzinger in 2002 (Fig. 7.43).16,17,19 The concept is similar to the twin-block concept in that it has guide planes that train the mandible forward on final closure, achieving the desired myofunctional effect (see Case Study 7.16). In the FMA, however, the guide planes are positioned buccally and are usually part of a cast framework. Modification of FMA. During function, the molars that retain the appliance undergo intrusive forces and tipping moments. The mandibular molars, for example, tend to tip mesially, which can lead to proclination of the anterior segment. These effects can be prevented by using skeletal anchorage to maintain the position of the lower molars. A modified cast FMA is currently being developed to allow skeletal anchorage.
Correction of Skeletal Discrepancies
a
b
c
d
Fig. 7.43a–e The Functional Mandibular Advancer (FMA, Forestadent). a The mechanical anterior guidance principle. b Components. c, d Clinical example: the guiding planes are at 60° to the occlusal plane, which allows predictable anterior positioning even for partial mouth-opening. (Images courtesy of Prof. G. Kinzinger, TÜnisforst, Germany.) e Modified version. Skeletal anchorage of the first mandibular molars prevents tipping and intrusion. The rigid connection between the mini-implant and the first molar enhances the stability of the anchorage set-up.
e
Orthodontic mini-implants are inserted distal to the mandibular second premolars to reinforce anchorage of the lower molars. The mini-implants are placed before the impressions for the fabrication of the modified FMA are taken, which allows the implants to be placed in the ideal position. The device is then applied in the post-insertion situation. After insertion of the mandibular mini-implants, upper and lower alginate impressions and a construction wax
bite are taken. The impression of the lower jaw needs to be sufficiently precise to reproduce the position of the mini-implants exactly. The laboratory will then produce a cast design including molar bands, guide planes, and connectors to the mini-implant head (Fig. 7.43e). After cementing of the elements, the residual space between the mini-implant head and the connector is filled with a flowable composite.
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Case Study 7.16 (Fig. 7.44) Patient: K.I., female, age 20. Diagnostic records: models, panoramic radiograph, lateral cephalometric radiograph, intraoral/extraoral photographs. Main findings: increased overjet, asymmetric occlusion with mandibular midline deviation to the right. Treatment aims: establish bilateral class I occlusion and coincident midlines using the Functional Mandibular Advancer (FMA).
1
2
Appliances: lingual self-ligating brackets, individually fabricated FMA. Archwire sequence: 0.012 SE and 0.016 SE preformed lingual archwires, 0.016 SS and 0.018 SS custom-bent archwires. Alternative treatment strategy: different Herbst appliance modifications, orthognathic surgery. Active treatment time: 14 months. Retention: vector retention with directional component (for example, retainer with a built-in FMA), bonded retainer.
3
Fig. 7.44 1–20 1–5 Before treatment: maxillary and
mandibular anterior crowding. Class II on the right, with mandibular shift.
4
5
CLINICAL PEARL Careful diagnosis of the masticatory apparatus, including palpation of the muscles of mastication and the temporomandibular joint, should form part of the initial diagnostic work-up in all patients, particularly when a temporomandibular disorder is suspected. The clinical diagnosis can be supported by diagnostic imaging
6
7
(magnetic resonance imaging). This patient presented with postero-superiorly directed loading of the joint, leading to anterior disk displacement with reduction, which was revealed by MRI. The treatment aim was stable repositioning of the disk. Anterior repositioning of the mandible should lead to recapturing of the disk.
8
6–10 Lingual self-ligating brackets from
5 to 5 with a preformed 0.012 SE lingual archwire.
Clinical pearl: Initial decompensation through leveling and aligning will reveal the full extent of the underlying skeletal discrepancy. The occlusion is subsequently corrected.
9
10
Correction of Skeletal Discrepancies
11
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13
11–15 A custom 0.016 stainless-steel archwire.
Clinical pearl: After insertion of the mandibular advancement appliance, proper function in the protruded position needs to be practiced with the patient.
14
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16
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18
16–20 Final result (on the day the appliance was removed).
19
20
CLINICAL PEARL Class II elastics are worn in order to maintain the results. Buccal cleats are bonded to the lower molars, and the elastics are suspended from the lingual brackets on 13 and 23 to the molar cleats which are easy to reach.
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Treatment continuous activation in which one size fits all (Fig. 7.45). This means that initial measurement of the space requirements is not necessary for fitting the system. The system is marketed as the Easy-Fit Jumper (Forestadent) (see Case Study 7.17). An appliance with similar properties is the SUS 2 (Sabbagh Universal Spring, Dentaurum).
Easy-Fit Jumper Most bite-jumping techniques use prefabricated parts, which are available in a number of sizes to reflect the physiological requirements of individual patients. Recognizing the problem of increased inventory and reactivation, Williams subsequently developed a system with
Fig. 7.45a–k a The Williams appliance can be screwed
and crimped onto the archwire and locked into place. Length adjustments are simple. b, c Mesial and/or distal adjustment of the rectangular tube (pivot), depending on the interbracket distance between maxillary 6 and 7 and mandibular 3 and 4. d, e Insertion of the mandibular archwire into the brackets (the pivot is placed between teeth 3 and 4). Locking of the brackets and distal cinch-back secures the wire in place. The pivot is arrested by crimping the tube mesially and distally using a pin-and-ligature cutter. f–h The guiding pin is inserted and secured with a screw. Tight fitting of the screw is important. The sleeve can be adjusted in length using a key that is part of the system. i–k Mandibular positioning: • Coincident dental midlines • Midlines coincident with facial midlines • Overcorrection of the sagittal mandibular position
a
b
c
d
e
f
i
g
j
h
k
Correction of Skeletal Discrepancies Case Study 7.17 (Fig. 7.46) Patient: L.P.S, female, age 13. Diagnostic records: models, panoramic radiograph, lateral cephalometric radiograph, intraoral/extraoral photographs. Main findings: class II/2, with a 100% deep bite and retrognathic mandible, tooth 42 completely blocked out lingually. Treatment aims: creating space for tooth 42, deep bite correction, and jumping the bite.
1
2
Appliances: self-ligating brackets, molar bands, Easy-Fit Jumper. Archwire sequence: 0.012 SE, 0.016 SE, 0.016 SS, 0.016 × 0.022 SE, 0.018 × 0.025 SE, 0.019 × 0.025 SS. Alternative treatment strategy: maxillary first premolar extraction, orthognathic surgery after cessation of growth. Active treatment time: 15 months. Retention: functional retention (twin-block modification, later removal of the advancement components possible).
3
Fig. 7.46 1–32 1–5 The situation before treatment:
overeruption and retroclination of the maxillary central incisors; mandibular crowding and lingually displaced 42. The dental and skeletal relationships are class II.
4
5
6
7
8
6–10 Self-ligating brackets and molar bands; a 0.012 SE archwire is inserted.
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10
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Treatment
11
12
13
11–13
Clinical pearl: Apart from “unlocking” the bite, palatal bite-blocks on the maxillary central incisors support protrusion and intrusion of those
teeth. A light piggyback archwire brings the mandibular right lateral incisor forward; the space is opened simultaneously with a coil-spring.
14
15
16
17
18
19
14–19 After initial leveling and alignment, the Easy-Fit Jumper (Williams appliance) was inserted for 6 months.
20
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22
23
24
25
20–25 The final result immediately before debonding, and post-treatment stability due to functional retention with a modified twin-block appliance.
Correction of Skeletal Discrepancies
26
27
28
26–28 Esthetic improvement after gingival contouring of the previously lingually excluded 42.
29, 30 Schwarz protusion plate for threedimensional retention of the final result. Errors and risks: A myofunctional appliance was used as a retention device, due to the high risk of relapse of the class II correction.
29
30
31–32 Marked improvement on both the sagittal and vertical planes.
31
32
Correction of Class III Malocclusions The prognosis of class III treatment needs to be carefully evaluated, as it depends on a number of etiological and hereditary factors. From an etiological point of view, it is important to distinguish whether the class III malocclusion is due to a hypoplastic maxilla, a hyperplastic mandible, or a combination of the two. Genetically predetermined enlargement of the lower jaw is particularly difficult to treat using orthodontic camouflage. The skeletal relationships often deteriorate during the pubertal growth spurt, and it seems impossible to estimate future mandibular development. In these cases, only serial superimpositions of the cephalogram can determine whether growth is slowing or has stopped. Orthognathic surgery can be considered once growth has largely been completed and the growth spurt has ceased. However, even if a mandibular set-back is planned at a later time point, orthopedic development of the maxilla and midface should be attempted in order to correct
problems such as a maxillary transverse deficiency or malar deficiency with reduced cheek prominence. Transverse discrepancies can be treated using skeletal expansion, as described in the previous section on “Space Creation by Expansion of Arches.” This is usually undertaken with a rapid maxillary expansion device such as the hybrid rapid palatal expander. After expansion and distraction of the midpalatal suture, it is thought that all the maxillary sutures will have loosened and that it will be easier to treat a hypoplastic maxilla orthopedically— although this concept has been questioned. The ideal time point for applying a face mask is either during or immediately after expansion of the maxilla. According to a number of studies, mainly based on cephalometrics, a sagittal maxillary traction device can be used in patients up to 12 years of age. However, some operators extend this recommendation to older age groups; patients need to be carefully informed about the potential for relapse, regardless of age group.
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Case Study 7.18 (Fig. 7.47) Patient: Y.M., male, age 14. Diagnostic records: models, panoramic radiograph, lateral cephalometric radiograph, intraoral/extraoral photographs. Main findings: skeletal class III with maxillary deficiency. Treatment aims: rapid palatal expansion and maxillary protraction.
1
Appliances: self-ligating brackets, molar bands, mini-implants, hybrid rapid palatal enlargement (RPE), Delairetype protraction facemask. Archwire sequence: 0.012 SE, 0.016 SE, 0.016 SS, 0.016 × 0.022 SE, 0.018 × 0.025 SE, 0.019 × 0.025 SS. Alternative treatment strategy: traditional RPE. Active treatment time: 12 months. Retention: three-dimensional retention.
2
3
Fig. 7.47 1–23 1–5 Self-ligating brackets, 0.012 SE archwire, mini-implants in place.
4
5
6
7
6 Hybrid rapid palatal enlarger (RPE) placed.
8
7 The hybrid RPE after 12 days of expan-
sion. It has palatal extension arms with anterior hooks welded in place to attach the elastics for maxillary protraction.
ERRORS AND RISKS Fixed-appliance treatment alone would decompensate the occlusion and would have led to worsening of the class III relationship; the facemask treatment allowed for compensation.
8 The protraction facemask is connected to the hybrid RPE (1⁄4, 6 oz) for 24 hours.
Correction of Skeletal Discrepancies
9
10
11
9–11 Almost ideal conditions 5 months into treatment.
12, 13 The maxillary and mandibular in-
cisors were flared as a result of treatment. However, a class I relationship was established with maxillary traction.
12
13
ERRORS AND RISKS The diagnostic records suggest a continuation of the unfavorable growth pattern. Treatment objectives therefore have to be clearly set, and patients need to be
informed about the possibility of a compromised result or the need for surgical correction of the skeletal problem.
14
15
16
17
18
19
14–19 The situation at the start of treatment and after 1 year of retention.
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Treatment
20
21
22
23
CLINICAL PEARL Patients with class III have a propensity to develop mandibular crowding as a consequence of dental compensation. Interproximal enamel reduction, fixed retention, or a combination of the two are often indicated. The extraction of one lower incisor can be a useful alternative.
20–23 Another example: class III with mandibular prognathism, which was treated with hybrid rapid palatal enlargement and maxillary protraction. 20 Before treatment. 21 At the end of treatment. 22 Before maxillary expansion. 23 12 days after expansion, followed by maxillary protraction.
Esthetic Treatment
Self-Ligating Ceramic Brackets
ceramic or composite material (Fig. 7.49). Esthetic archwires may also be considered, but these are not usually available in different tooth colors and can thus be just as visible as metal archwires, so that they do not always offer any marked esthetic improvement.
Although orthodontic treatment in adults is more common now than in the past, adults are often still unwilling to wear particularly noticeable appliances. Esthetic solutions are therefore preferred, and this applies regardless of the ligation mechanism involved. The advantage of using self-ligating esthetic brackets over metal brackets, aside from the biomechanical advantages, lies in their reduced tendency to discolor (which affects the elastomeric element in conventional ligation, particularly when consuming foodstuffs containing colors). The most sensitive area for adults is the “social six”—the anterior labial segment from canine to canine (Fig. 7.48). For esthetically demanding patients, most manufacturers produce esthetic self-ligating brackets, which are made of either
Fig. 7.48 The esthetic zone for orthodontic treatment.
Esthetic Treatment
a
b
c
d
e
f
g
h
i
k
l
j
Fig. 7.49a–l Esthetic self-ligating brackets (SLBs) and their
appearance. a–c A metal bracket for comparison. d–f Ceramic SLBs (In-Ovation C).
g–i Ceramic SLBs in the maxillary dentition (SmartClip, g, h) and traditional ceramic brackets in the mandibular dentition (i). j–l Ceramic SLBs in the maxillary dentition (QuicKlear, j, k) and metal SLBs in the mandibular dentition (l).
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Case Study 7.19 (Fig. 7.50) Patient: C.O., female, age 17. Diagnostic records: models, panoramic radiograph, lateral cephalometric radiograph, intraoral/extraoral photographs. Main findings: class I occlusion with misalignment of the anterior dentition. Treatment aims: improving anterior esthetics.
1
2
Appliances: Self-ligating brackets, molar bands, interproximal reduction (IPR). Archwire sequence: 0.012 SE, 0.016 SE, 0.016 × 0.022 SE, 0.018 × 0.025 SE, 0.019 × 0.025 SS. Alternative treatment strategy: n/a. Active treatment time: 9 months. Retention: maxillary and mandibular bonded retainers.
3
Fig. 7.50 1–25 1–5 Maxillary and mandibular anterior
crowding. The patient requested cosmetic improvement.
4
5
6
7
8
6–10 Self-ligating brackets bonded and a 0.012 esthetic SE archwire in place.
9
10
Esthetic Treatment CLINICAL PEARL 11 Ceramic self-ligating brackets from canine to canine and esthetic archwires often improve acceptance by patients, especially in adults.
11
12
13
14 12–16
Clinical pearl: If the treatment aim includes improvement of smile esthetics and reduction of buccal corridors, maxillary first and second bicuspid brackets can be turned upside down, so that the torque value will change from –7° to + 7° (Roth prescription).
15
16
17, 18 Comparison of buccal corridors before and after the altered inclination.
07-050-17 fehlt
17
18
19, 20 Comparison of lateral cephalo-
grams before and after treatment. The incisor inclination did not increase markedly, due to interproximal enamel reduction.
19
20
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Treatment
21
22
23
21–25 The final result (before bonding of the fixed retainers).
24
25
CLINICAL PEARL Regardless of whether hybrid rapid palatal expansion, a Frog appliance, or an Easy-Fit Jumper is used, ceramic self-ligating brackets improve the esthetic appearance during treatment and thus increase patient acceptance.
1
2
Fig. 7.51 1–3
3
Esthetic Treatment
Lingual Self-Ligating Brackets Lingual appliances have intermittently been reinvented and further developed during the last 30 years, but they are still not routinely used in orthodontic practices. There are a number of reasons for this, but it is mainly due to the difficulty of bracket placement and archwire changes. The lingual surfaces of the teeth are also much more inconsistent between individuals in comparison with the labial surfaces. In addition, the reduced interbracket distance makes the archwires less efficient. Applying the force lingual to the center of resistance sometimes creates different biomechanical effects from those obtained with traditional labial appliances.27 For precise three-dimensional programming and patient-specific, individualized treatment, extensive laboratory procedures are necessary, including an individualized set-up for the dentition with manufacturing of individualized brackets and archwires. To allow precise three-dimensional preprogramming of the appliances, laboratory steps are required in which the teeth are measured, set-ups are created, bracket bases are customized, and brackets are transferred to the dentition using transfer aids for indirect bonding.33 Simplified lingual techniques have been developed in recent years that avoid the need for complex programming and individualization of lingual appliances. This makes the system a more cost-effective alternative in comparison with fixed labial appliance treatment. These systems are usually designed for alignment of the anterior teeth only and not for treatment of complex problems, which require correction of the occlusion (Fig. 7.52). Some lingual brackets have self-ligating mechanisms incorporated. The present authors mainly use the two-dimensional lingual bracket system developed by Philippe. This can often be used as an alternative to the more complex threedimensional bracket systems and provides good results for limited treatment with minor tooth movement.22 More recently, this technique has been propagated by Cacciafesta’s group.21 As the name implies, the twodimensional system only allows two-dimensional control of tooth movement. Leveling and alignment, with correction of rotations and angulation changes in individual teeth, are possible. However, this bracket does not have a rectangular slot, so that controlled torque expression is not possible (Fig. 7.53). However, the lack of a rectangular slot and a sophisticated ligation mechanism allows a low-
a
Fig. 7.52 Lingual self-ligating brackets from various manufactu-
rers. Direct bonding without set-up is possible with the In-Ovation L, Phantom, and 2 D Philippe. To ensure appropriate positioning, In-Ovation L has a well-contoured base, while the Phantom bracket comes with a positioning gauge that has to be removed after bonding. The 2 D Philippe can be easily positioned lingually due to its small base. The Evolution LT and 3 D Philippe require a set-up with customization of the bracket base. Displayed from left to right: Evolution LT (Andenta), 2 D Philippe (Forestadent), In-Ovation L (GAC), Phantom (Gestenco).
a
b
Fig. 7.53a, b The basic configuration of the two-dimensional
lingual brackets designed by Philippe. The brackets have self-ligating wings that are closed by bending them toward the bracket base after the wire has been inserted. The inner surface is rounded off, which means that three-dimensional control is not possible.
profile design at 1.4 mm. This improves patient comfort, and speech impediments are not as significant as they often are with other lingual bracket types. These brackets are bonded directly onto the tooth (i.e., without complex laboratory procedures). Vertical positioning of the brackets can be obtained by using a ruler or a gauge (Fig. 7.54). Due to the variability of the lingual anatomy of the teeth, it is often necessary to individualize
b
c
Fig. 7.54a–c Establishing the vertical position for lingual brackets. a A measurement gauge with 1/10 mm scale and an integrated pencil for marking the height on the conditioned enamel surface. b, c Intraoral application of the gauge and resulting marks.
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Treatment
the archwire to achieve the best possible alignment. As the bracket only translates two-dimensional information onto the tooth (i.e., rotation, angulation, and height), only one bracket is used for all teeth. Lingual archwires can be individualized using prefabricated mushroom-shaped wires, which are available in a number of sizes (Fig. 7.55). The decision on whether to use a two-dimensional approach or a more complex lingual appliance system depends on the diagnosis and the desired treatment
outcome. This system is particularly useful for esthetic treatment of anterior crowding, or mild to moderate relapse after previous orthodontic treatment (see also the section on “Management of Relapse” in Chapter 9). If correction of torque values is needed, consideration should be given to using a three-dimensional lingual system, which is more suitable for achieving the desired treatment aims.
Fig. 7.55a–e a–c Selecting the preformed lingual archwires using a template.
d, e Two-dimensional lingual brackets with
preformed lingual wires of 0.012, 0.014, and 0.016.
a
c
b
d
e
Esthetic Treatment Case Study 7.20 (Fig. 7.56) Patient: M.S., female, age 17. Diagnostic records: models, panoramic radiograph, lateral cephalometric radiograph, intraoral/extraoral photographs. Main findings: retained tooth 63 and impacted tooth 23.
1
2
4
5
Treatment aims: creating space for tooth 23, exposure, and guided eruption. Appliances: two-dimensional lingual self-ligating bracket, preformed archwires, later individual archwires. Archwire sequence: 0.012 SE, 0.014 SE, 0.016 SE, 0.016 SS. Alternative treatment strategy: n/a. Active treatment time: 11 months. Retention: bonded lingual retainer.
3
Fig. 7.56 1–18 1–7 The initial situation, with a palatally
impacted tooth 23.
6
7
NOTE
CLINICAL PEARL
In Fig. 7.56, 5 and 6 show the discrepancy between the perceived canine location on the panoramic radiograph and the actual location as shown in the three-dimensional reconstruction on low-dose computed tomography.
Cone-beam computed tomography (CT) or low-dose conventional CT can be useful for accurately establishing the location of impacted teeth, and this additional information is often helpful in treatment planning.
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8
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Treatment
9
10
12
13
8–13 Piggyback technique for positioning of tooth 23, with a 0.012 SE segmental wire and stainless-steel base arch.
14
15
16
14–18 After 1 year of retention, tooth 23 shows a stable position.
17
18
Esthetic Treatment Case Study 7.21 (Fig. 7.57) Patient: P.D., female, age 44. Diagnostic records: models, panoramic radiograph, lateral cephalometric radiograph, intraoral/extraoral photographs. Main findings: mandibular anterior crowding. Treatment aims: alignment of lower incisors.
1
2
Appliances: two-dimensional lingual self-ligating bracket, preformed archwires, later individual archwires, interproximal reduction. Archwire sequence: 0.012 SE, 0.014 SE, 0.016 SE, 0.016 SS. Alternative treatment strategy: extraction of a single mandibular incisor. Active treatment time: months. Retention: mandibular bonded retainers.
3
Fig. 7.57 1–16 1–5 Class I occlusion with mandibular an-
terior crowding.
4
5
ERRORS AND RISKS In single-arch treatment, it is imperative to avoid changing the arch shape or the incisor inclination, as otherwise the arch coordination can be lost. Interprox-
imal reduction may be needed to create space and resolve crowding.
6–9 Lingual self-ligating brackets from 7
to 7 and BioLingual archwires in the sequence 0.012 SE, 0.014 SE, and then 0.016 SE stainless steel. At each archwire change, interproximal reduction (IPR) was performed from 5 to 5. Despite the IPR, the final result is potentially unstable and requires permanent retention.
6
7
8
9
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Treatment
10
11
12
10–14 The good occlusion was maintained.
13
14
15, 16 Before and after treatment.
15
16
CLINICAL PEARL Interproximal enamel reduction (IPR) can be an alternative to extraction treatment. Fluoridation and patient consent need to be observed.
Esthetic Treatment Case Study 7.22 (Fig. 7.58) Patient: L.S., male, age 23. Diagnostic records: models, panoramic radiograph, lateral cephalometric radiograph, intraoral/extraoral photographs. Main findings: esthetically unsatisfactory anterior alignment. Treatment aims: establishing anterior esthetics.
1
2
Appliances: two-dimensional lingual self-ligating bracket, preformed archwires, later individual archwires, interproximal reduction. Archwire sequence: 0.012 SE, 0.016 SE, 0.016 SS. Alternative treatment strategy: n/a. Active treatment time: 19 months. Retention: vacuum-formed retainer, followed by bonded retainers.
3
Fig. 7.58 1–20 1–5 Maxillary and mandibular anterior
crowding. Class I occlusion on the right side and class II tendency on the left side. There is a supernumerary molar 29.
4
5
6
7
8
6–10 The initial treatment phase, with 0.012 SE archwires in both arches.
9
10
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7
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Treatment
12
13
11–15 Treatment progress with 0.016 SE archwires in both arches.
14
15
16
17
18
16–20 The treatment result after 1 year
of retention with a vacuum-formed retainer in the maxilla and a bonded retainer in the mandible. The supernumerary 29 was left in place.
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